System and method for endoluminal and translumenal therapy

ABSTRACT

A robotic instrument system comprises a controller configured to control actuation of at least one servo motor and an elongate instrument configured to move in response to actuation of the at least one servo motor, wherein the controller controls positioning of the instrument based at least in part upon an electroanatomic model of the neural plexus adjacent the renal artery.

CROSS REFERENCE TO RELATED APPLICATIONS

The present application claims the benefit under 35 U.S.C. §119 to U.S. Provisional Patent Application No. 61/434,797, filed Jan. 20, 2011. The foregoing application is hereby incorporated herein by reference in its entirety.

FIELD OF THE INVENTION

The invention relates generally to minimally invasive medical techniques, and more particularly to therapeutic denervation treatments using endolumenal or translumenal instruments such as electromechanically or robotically operated catheters.

BACKGROUND

Elongate medical instruments, such as catheters, are utilized in many types of medical interventions. Many such instruments are utilized in what have become known as “minimally invasive” diagnostic and interventional procedures, wherein small percutaneous incisions or natural orifices or utilized as entry points for instruments generally having minimized cross sectional profiles, to mitigate tissue trauma and enable access to and through small tissue structures. One of the challenges associated with minimizing the geometric constraints is retaining functionality and controllability. For example, some minimally invasive instruments designed to access the cavities of the blood vessels and/or heart have steerable distal portions or steerable distal tips, but may be relatively challenging to navigate through tortuous vascular pathways with varied tissue structure terrain due to their inherent compliance. Even smaller instruments, such as guidewires or distal protection devices for certain vascular and other interventions, may be difficult to position due to their relatively minimal navigation degrees of freedom from a proximal location, and the tortuous pathways through which operators attempt to navigate them. To provide additional navigation and operational functionality options for minimally invasive interventions, it is useful to have an instrument platform that may be remotely manipulated with precision, such as the robotic catheter system available from Hansen Medical, Inc. under the tradename Sensei®. The elongate instruments associated with such a system may be navigated not only within the cardiovascular system, but also within other body lumens and cavities, such as those of the respiratory, gastrointestinal, urinary, and reproductive systems to address various maladies of the body, including but not limited to various paradigms cardiovascular disease. One such cardiovascular disease area of interest is hypertension, or high blood pressure, and it has been found that aspects of hypertension may be controlled with denervation therapy of the nerves of the renal plexus adjacent the renal artery. It would be valuable to have further interventional options than are presently available to address renal plexus denervation therapy.

SUMMARY

One embodiment is directed to a robotic instrument system, comprising a controller configured to control actuation of at least one servo motor; and an elongate instrument configured to move in response to actuation of the at least one servo motor; wherein the controller controls positioning of the instrument based at least in part upon an electroanatomic model of the neural plexus adjacent the renal artery. The system further may comprise a master input device operatively coupled between the remotely-steerable elongate deployment member and the controller, the master input device configured to receive commands from an operator and produce control signals to be used by the controller to operate the elongate instrument. The elongate instrument may be an electromechanically steerable catheter. The system further may comprise a robotic instrument driver operatively coupled between the elongate instrument and the controller, the robotic instrument driver being configured to move one or more control elements of the elongate instrument in response to signals transmitted from the controller to cause navigation movement of the elongate instrument. The elongate instrument may be coupled to a treatment element configured to be at least partially pierced into nearby tissue structures. The system further may comprise one or more localization sensors coupled to a distal portion of the elongate instrument and configured to facilitate computation of a location of said distal portion relative to a coordinate system, wherein the localization sensor comprises an element selected from the group consisting of: an ultrasound transducer, an electromagnetic flux sensor, a fiber Bragg local deflection sensor, a resistive strain gauge, a potential difference sensor, and a current sensor. The system further may comprise one or more imaging elements coupled to the elongate instrument selected from the group consisting of: an ultrasound transducer, an optical fiber, and an imaging chip. One imaging element may be an optical fiber, and the system further may comprise an interferometry system configured to analyze transmitted and reflected light signals. The interferometry system may be configured to create an OCT image of a portion of a targeted tissue structure. The electroanatomic model may comprise one or more spatial points of presence of neural fibers comprising the neural plexus relative to other nearby anatomy. The controller may be configured to advance the treatment element across at least one tissue wall toward the neural plexus. The controller may be configured to automatically move the elongate instrument based at least in part upon the electroanatomical model. The controller further may be configured to control positioning of the instrument based at least in part upon a renin level detected in the blood. The controller further may be configured to control a level of current flow to an ablation electrode operatively coupled to the instrument based at least in part upon a renin level detected in the blood. The controller may be configured to superimpose an anatomic map upon an electrical mapping to assist in the identification of electrical foci within the neural plexus adjacent the renal artery.

Another embodiment is directed to a method for conducting a denervation process upon the neural plexus adjacent the renal artery, comprising navigating a steerable catheter into the renal vein; imaging targeted portions of the neural plexus from inside of the renal vein to create an anatomic map of the targeted portions; creating an electrical mapping of one or more neural strands comprising the targeted portions; and denervating the targeted portions utilizing a treatment element coupled to the steerable catheter, based at least in part upon the anatomic map and electrical mapping. The steerable catheter may be a robotic catheter operatively coupled to the control computing device and configured to move in response to control signals from a master input device configured to manually operated by an operator. Creating an electrical mapping may comprise stimulating a first portion of a nerve strand and detecting conduction of the stimulation at a second portion of the nerve strand longitudinally displaced from the first portion. The method further may comprise associating a nerve anatomical location with each of the first and second portions of the nerve strand. The method further may comprise associating a renal vein anatomical location from the anatomic map with each of the nerve anatomical locations to form an electroanatomical map. The treatment element may comprise an electrode, and denervating may comprise passing current through the electrode. Denervating further may comprise placing the electrode at an endolumenal location adjacent a targeted portion of the neural plexus. Denervating further may comprise placing the electrode at a translumenal location adjacent a targeted portion of the neural plexus. The method further may comprise advancing the treatment element relative to a distal portion of the steerable catheter. The method further may comprise superimposing the anatomic map upon the electrical mapping to assist in the identification of electrical foci within the neural plexus adjacent the renal artery. Creating an electrical mapping may comprise stimulating a first portion of a nerve strand and detecting conduction of the stimulation in any other portion of the associated neural plexus.

Another embodiment is directed to a system for conducting a denervation of the neural plexus adjacent the renal artery, comprising: a remotely-steerable elongate deployment member configured to be navigated into the renal artery; an expandable intravascular treatment member coupled to a portion of the elongate deployment member, the expandable member comprising one or more circuit elements operatively coupled to one or more tissue probing tips, such that upon expansion of the expandable member from a collapsed state to an expandable state, the probing tips protrude substantially perpendicularly from an outer surface of the expandable member and into one or more walls of the renal artery; and an energy source operatively coupled to the circuit elements and probing tips, the energy source configured to cause current to flow from the probing tips and cause localized heating sufficient to denervate nearby neural tissue. The remotely-steerable elongate deployment member may be electromechanically actuated. The system further may comprise one or more localization sensors coupled to a distal portion of the remotely-steerable elongate deployment member and configured to facilitate computation of a location of said distal portion relative to a coordinate system, wherein the localization sensor comprises an element selected from the group consisting of: an ultrasound transducer, an electromagnetic flux sensor, a fiber Bragg local deflection sensor, a resistive strain gauge, a potential difference sensor, and a current sensor. The system further may comprise one or more imaging elements coupled to the remotely-steerable elongate deployment member selected from the group consisting of: an ultrasound transducer, an optical fiber, and an imaging chip. One imaging element may be an optical fiber, and the system further may comprise an interferometry system configured to analyze transmitted and reflected light signals. The interferometry system may be configured to create an OCT image of a portion of a targeted tissue structure. The system further may comprise a lens optically coupled to the optical fiber. The lens and optical fiber may define a field of view that is oriented along a longitudinal axis of the elongate deployment member. The lens and optical fiber may define a field of view that is oriented substantially perpendicular to a longitudinal axis of the elongate deployment member. The expandable intravascular treatment member may comprise a stent.

Another embodiment is directed to a method of closing a translumenal access port defined through a side of a lumen, comprising: applying a circumferential clip from the inside of the lumen to effect a temporary closure, the clip being urged into a closed position by an inflatable actuating member local to the clip and controlled remotely by an operator; and deploying a stent over the closed position of the clip. The method further may comprise imaging tissue structures adjacent the translumenal access port from inside of the lumen. Imaging may comprise activating one or more ultrasound transducers. The circumferential clip may comprise a shape selected to circumferentially surround the translumenal access port. Applying the clip may comprise urging one or more barb members of the clip into tissue surrounding the translumenal access port. The inflatable actuating member may comprise an inflatable bladder and wherein applying the clip comprises causing the bladder to inflate.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 illustrates certain aspects of renal vascular and neuroanatomy.

FIG. 2 illustrates a close-up view of a portion of a renal artery as well as certain portions of an associated renal nerve plexus.

FIG. 3 illustrates a robotic catheter system configured for conducting minimally invasive medical interventions.

FIG. 4 illustrates an instrument driver and instrument assembly of a robotic catheter system configured for conducting minimally invasive medical interventions.

FIGS. 5A-5D illustrate various aspects of an instrumentation system for conducting a trans-lumenal renal plexus denervation procedure with one or more controllably steerable instruments and one or more controllably expandable members.

FIGS. 6A-6B illustrate various aspects of a trans-ureteral renal nerve plexus intervention utilizing the subject remotely steerable instrument system.

FIG. 7 depicts a close up partial view of renal, cardiovascular, and associated neuroanatomy in the abdomen adjacent the kidney.

FIG. 8 illustrates various aspects of a trans-ureteral renal plexus denervation intervention.

FIG. 9 illustrates various aspects of a trans-arterial renal plexus denervation intervention wherein instrumentation is taken across a portion of a wall of the celiac trunk artery.

FIG. 10 illustrates various aspects of a trans-arterial renal plexus denervation intervention wherein instrumentation is taken across a portion of a wall of the superior mesentary artery.

FIG. 11 illustrates various aspects of a trans-venous renal plexus denervation intervention wherein instrumentation is taken across a portion of a wall of the vena cava.

FIG. 12 illustrates various aspects of a trans-venous renal plexus denervation intervention wherein instrumentation is taken across a portion of a wall of the renal vein.

FIG. 13 illustrates various aspects of a process for creating a trans-lumenal access port from inside of a subject tissue lumen or structure, utilizing the access port for a diagnostic or interventional procedure, and closing the access port from inside of the subject tissue lumen.

FIGS. 14A-14G illustrate various aspects of a system for renal neuroplexus diagnostics and intervention in accordance with the present invention.

FIGS. 15A-15D illustrate various aspects of a system for renal neuroplexus diagnostics and intervention in accordance with the present invention, wherein OCT imaging techniques may be employed.

FIGS. 16-21 illustrate process embodiments in accordance with the present invention.

FIG. 22 illustrates an embodiment wherein a longitudinally displaced pattern may be used in a denervation treatment.

FIGS. 23A-23C illustrate an embodiment wherein a pullback technique may be utilized in a denervation treatment with a pre-shaped spiral instrument.

FIG. 24 illustrates an embodiment wherein an evacuated volume may be utilized to assist with a denervation treatment wherein an expandable device comprising one of more circuit elements is utilized in a denervation treatment.

FIGS. 25A and 25B illustrate embodiments wherein two or more guide instrument assemblies may be utilized to conduct a denervation treatment.

FIGS. 26A-26C illustrate an embodiment wherein a pullback technique may be utilized in a denervation treatment with a pre-shaped J-curve instrument.

FIGS. 27A-27C illustrate various aspects of manufacturing and behavior details of a pre-shaped spiral instrument embodiment.

FIGS. 28A and 28B illustrate various details of a pre-shaped J-curve instrument embodiment.

FIGS. 29-34 illustrate process embodiments in accordance with the present invention.

DETAILED DESCRIPTION

Referring to FIG. 1, the kidneys (2) are shown in relation to the aorta (4), vena cava (6), ureters (8), renal veins (12) and portions of the neural anatomy of the renal plexus (14), which is coupled to the renal arteries (10). Referring to FIG. 2, a close-up orthogonal view of a portion of a renal artery (10) is shown, with bands of contractile smooth muscle tissue (18) surrounding the longitudinal axis (16) circumferentially, and with strands of renal nerves (20) coupled to the renal artery (10), generally longitudinally along the renal artery (10). These strands of renal nerves (20) comprise the renal nerve plexus, or renal plexus, which may be embedded within the adventitia of the renal artery (10). This nerve plexus extends along the renal artery until it joins the parenchyma of the kidney (2). As briefly described above, hypertension and other diseases such as heart failure and chronic kidney disease are a few of the disease states that result from chronic activation of the sympathetic nervous system, especially the renal sympathetic nervous system, which comprises the renal plexus. Chronic activation of the sympathetic nervous system is a maladaptive response that drives the progression of these disease states. Indeed, the renal sympathetic nervous system has been identified as a major contributor to the complex pathophysiology of hypertension, various states of volume overload (such as congestive heart failure), and progressive heart disease, in experimental and clinical research studies. Given the knowledge that hypertension is commonly neurogenic, there are new clinical intervention paradigms evolving whereby an attempt is made to locate and ablate strands of renal nerves (20) comprising the renal plexus from the inside of the renal artery, via an endovascular approach. Various challenges are presented with such an approach, including locating and appropriately denervating the nerve strands without damaging or necrosing the tissue of the renal artery wall. In investigating extravascular approaches (i.e., approaching the renal plexus from outside of the walls of the renal artery), it has been determined that one of the key challenges is controllably navigating and operating an instrument to a retroperitoneal location whereby the renal plexus may be more directly denervated via radiofrequency ablation or other techniques. An electromechanically, or “robotically”, operated elongate instrument control system provides important functionality for such a challenge.

Referring to FIG. 3, a robotic catheter system is depicted having an operator workstation (210) comprising a master input device (206), control button console (208), and a display (204) for the operator (202) to engage. In the depicted embodiment, a controller or control computer configured to operate the various aspects of the system is also located near the operator (202). The controller (212) comprises an electronic interface, or bus (248), configured to operatively couple the controller (212) with other components, such as an electromechanical instrument driver (164), RF generator (214), localization system (216), or fiber bragg shape sensing and/or localization system (218), generally via electronic leads (232, 230, 236, 234, 240, 238, 242, 244, 246, 226).

Electromechanically or robotically controlled catheter systems similar to that depicted in FIG. 3 are available from Hansen Medical, Inc. under the tradename Sensei®, and described, for example, in U.S. patent application Ser. Nos. 11/481,433, 11/073,363, 11/678,001 (“Intellisense”) and 11/637,951, each of which is incorporated by reference in its entirety. In the depicted embodiment, the controller (212) preferably is operatively coupled (232) to the RF generator (214) and configured to control outputs of the RF generator (214), which may be dispatched via electronic lead (230) to the disposable instrument assembly (166). Similarly, the controller (212) preferably is operatively coupled (236) to a localization system, such as an electromagnetic or potential difference based localization system (216), such as those available under the tradenames CartoXP® and EnSite® from Biosense Webster, Inc., and St. Jude Medical, Inc., respectively. The localization system (216) preferably is operatively coupled via one or more leads (234) to the instrument assembly (166), and is configured to determine the three dimensional spatial position, and in certain embodiments orientation, of one or more sensors coupled to a distal portion of the instrument assembly relative to a coordinate system relevant to the controller and operator, such as a world coordinate system. Such position and/or orientation information may be communicated back to the controller (212) via the depicted electronic lead (236) or other signal communication configuration such as a wireless data communication system (not shown), to enable the controller (212) and operator (202) to understand where the distal portion of the instrument assembly (166) is in space—for control and safety purposes. Similarly, a fiber opticlocalization and/or shape sensing system (218) may be coupled between the controller (212) and instrument assembly (166) to assist with the determination of position and shape of portions of the instrument assembly, thermal sensing, contact sensing, and load sensing, as described, for example, in the aforementioned incorporated patent applications.

Various types of shape sensing fibers may be used in the fiber optic localization and/or shape sensing system (218). It is well known that by applying the Bragg equation (wavelength=2*d*sin(theta)) to detect wavelength changes in reflected light, elongation in a diffraction grating pattern positioned longitudinally along a fiber or other elongate structure maybe be determined. Further, with knowledge of thermal expansion properties of fibers or other structures which carry a diffraction grating pattern, temperature readings at the site of the diffraction grating may be calculated. “Fiberoptic Bragg grating” (“FBG”) sensors or components thereof, available from suppliers such as Luna Innovations, Inc., of Blacksburg, Va., Micron Optics, Inc., of Atlanta, Ga., LxSix Photonics, Inc., of Quebec, Canada, and Ibsen Photonics AIS, of Denmark, have been used in various applications to measure strain in structures such as highway bridges and aircraft wings, and temperatures in structures such as supply cabinets.

The use of such technology in shapeable instruments is disclosed in commonly assigned U.S. patent application Ser. Nos. 11/690,116; 11/176,598; 12/012,795; 12/106,254; 12/507,727; 12/192,033; 12/236,478; and 12/837,440. The entirety of each of the above applications is incorporated by reference herein.

In an alternative variation, a single mode optical fiber is drawn with slight imperfections that result in index of refraction variations along the fiber core. These variations result in a small amount of backscatter that is called Rayleigh scatter. Changes in strain or temperature of the optical fiber cause changes to the effective length of the optical fiber. This change in the effective length results in variation or change of the spatial position of the Rayleigh scatter points. Cross correlation techniques can measure this change in the Rayleigh scattering and can extract information regarding the strain. These techniques can include using optical frequency domain reflectometer techniques in a manner that is very similar to that associated with low reflectivity fiber gratings. A more complete discussion of these methods can be found in M. Froggatt and J. Moore, “High-spatial-resolution distributed strain measurement in optical fiber with Rayleigh scatter”, Applied Optics, Vol. 37, p. 1735, 1998 the entirety of which is incorporated by reference herein.

Methods and devices for calculating birefringence in an optical fiber based on Rayleigh scatter as well as apparatus and methods for measuring strain in an optical fiber using the spectral shift of Rayleigh scatter can be found in PCT Publication No. W02006099056 filed on Mar. 9, 2006 and U.S. Pat. No. 6,545,760 filed on Mar. 24, 2000 both of which are incorporated by reference herein. Birefringence can be used to measure axial strain and/or temperature in a waveguide. Using Rayleigh scatter to determine birefringence rather than Bragg gratings offers several advantages. First, the cost of using Rayleigh scatter measurement is less than when using Bragg gratings. Rayleigh scatter measurement permits birefringence measurements at every location in the fiber, not just at predetermined locations. Since Bragg gratings require insertion at specific measurement points along a fiber, measurement of Rayleigh scatter allows for many more measurement points. Also, the process of physically “writing” a Bragg grating into an optical fiber can be time consuming as well as compromises the strength and integrity of the fiber. Such drawbacks do not occur when using Rayleigh scatter measurement.

In one embodiment, an optical fiber sensor (238), which may or may not include Bragg gratings, may be positioned between the distal tip of one or more instruments in the assembly and coupled proximally to the optical fiber sensor interrogator (218) in a manner described in U.S. Provisional Patent application No. 61/513,488 the entirety of which is incorporated by reference herein, and outputs from such system may be electronically communicated (240) to the controller (212) to facilitate control and safety features, such as closed loop shape control of one or more portions of the instrument assembly, as described, for example, in the aforementioned incorporated references. A feedback and control lead (226) is utilized to operatively couple the instrument driver (164) to the controller. This lead (226) carries control signals from the controller (212) to various components comprising the instrument driver (164), such as electric motors, and carries control signals from the various components of the instrument driver (164), such as encoder and other sensor signals, to the controller (212). The instrument driver (164) is coupled to the operating table (222) by a setup structure (220) which may be a simple structural member, as depicted, or a more complicated movable assembly, as described in the aforementioned incorporated references. A bus configuration (248) couples the various depicted leads (226, 246, 244, 242, 240, 236, 232) with the controller (212). Alternatively, wireless configurations may be utilized.

Referring to FIG. 4, an orthogonal view of an instrument driver (164) and instrument assembly (166) is depicted, this configuration having the ability to monitor loads applied to working members or tools placed through a working lumen defined by the instrument assembly (166). In this embodiment, such loads are determined with load sensors (168) located within the housing of the instrument driver, as described in the aforementioned incorporated references. In other embodiments, loads imparted to various tools or aspects of the instrument assembly (166) may be monitored using load sensors or components thereof which are embedded within or coupled to distal portions (170) of such tools or instrument assembly portions.

Referring to FIGS. 5A-5D, various closer views of aspects of instrument embodiments in accordance with the present invention are shown. Referring to FIG. 5A, a steerable sheath instrument (22) is depicted having a proximal interface (shown in the aforementioned incorporated by reference disclosures in reference to robotic sheath instrument embodiments) configured to be removably and driveably coupled to an instrument driver (164) such as that depicted in FIG. 4. The distal portion of the sheath instrument (22) comprises an expandable member such as a balloon, which may be controllably expanded via an inflation lumen (42), as shown in the detail view of FIG. 5B. Also shown in FIGS. 5A and 5B is an elongate steerable guide instrument (24) which may be proximally coaxially positioned through a guide insertion lumen (44) defined into the sheath instrument (22), and distally directed out through a side port formed through the balloon member (26), after being routed through an arcuate portion (46) of the guide insertion lumen (44). With the balloon member (26) in an inflated or deflated state, the depicted instrument assembly may be placed through a lumen and utilized to create a side port across the wall of the lumen. In one embodiment, a needle may initially be advanced through the sheath instrument lumen (44, 46) and across the subject tissue wall, followed by a dilator instrument and/or guidewire, which may be followed by the guide instrument (24) in an over-the-wire type technique using a working lumen defined into the guide instrument (24). As shown in FIGS. 5A and 5B, the distal portion of the elongate guide instrument (24) may be outfitted with one or more ultrasound transducers (28), one or more localization sensors (30), and one or more treatment elements (such as a radiofrequency electrode, a cryoablation reservoir, a high intensity focused ultrasound treatment transducer, a laser or other radiation emitter, or the like 32) which may be utilized to denervate nerve strands, such as those of the renal plexus. In another embodiment, the distal portion of the guide instrument (24) may be operatively coupled to an antenna, such as a microwave antenna, to sense reflected radiation, such as blackbody radiation, which may be correlated to the temperature of nearby tissues, as described, for example, in U.S. patent application Ser. No. 12/833,927, which is incorporated by reference herein in its entirety. Such an embodiment allows for direct sensing of thermal conditions in nearby tissue structures of interest—as opposed to other competing techniques such as thermocouples placed adjacent RF heating electrodes, which are more aptly configured to read the temperature of the electrodes rather than nearby tissues.

Referring to the close-up view of FIG. 5B, the side port of the balloon member (26) comprises a lumen port closure configuration having one or more closure clip elements (34) constrained in an open configuration by the geometry of the balloon member (26) to which it is coupled. Upon controllable inflation of a small clip deployment bladder (38) coupled to the balloon member (26) using an inflation lumen (40), the clip (34) may be advanced outward, and small barb-like fastening members (36) configured to fasten to nearby tissue structures upon exposure and mild advancement load from the deployment bladder (38) and/or balloon member (26) inflation will engage nearby tissue structures, while the clip (34) simultaneously will become unconstrained from its coupling with the structure of the balloon member (26) and will be free to resume an unloaded configuration, preferably configured to coapt the tissue around the circumference of the access port toward itself. Suitable clips made from bioinert metals such as nitinol are available from Medtronic Corporation and were invented by Coalescent Surgical, Inc. and cleared by the FDA for a different medical application (closure of vascular anastomosis). The fastening features (36) may be sintered onto the clips, welded, coupled with a preferably bioinert adhesive, or formed or etched into the same structure that comprises the fastening element (36). Referring ahead to FIG. 13, a process for utilizing a configuration such as that depicted in FIGS. 5A and 5B to create and subsequently close a lumen side port is illustrated.

Referring to FIG. 13, after positioning an expandable balloon member in a contracted form to a desired insertion location and orientation (i.e., roll orientation relative to the longitudinal axis commonly associated with a lumen) (148), the expandable balloon member maybe controllably inflated to substantially occlude the body lumen (with the exception of flow which may be facilitated through a working through-lumen of a subject sheath instrument) and create a relatively low-level hoop tension in portions of the body lumen adjacent to the expanded balloon member (150). An elongate diagnostic and/or interventional instrument may then be advanced out of a side port of the expandable balloon member (in one embodiment, as described above, in an over-the-needle, wire, or dilator configuration), creating a trans-lumenal access port (152). Using this access port, a diagnostic and/or interventional procedure may be conducted translumenally with one or more elongate instruments (154). When the interventional procedure has been completed, the elongate instruments may be retracted (156) and a controlled closure of the translumenal access port executed by urging the one or more closure clips away from a housing depression formed in the balloon member, and into at least a portion of the tissue structure adjacent the translumenal access port, with the one or more clips maintaining their constrained (i.e., constrained until they are uncoupled from the balloon member housing interface) configurations as they are fastened to the nearby tissue (158). A bladder and associated pressure control lumen, as shown in FIG. 5B, for example, may be utilized to controllably advance the one or more clips outward, as described above. With the one or more closure clips fastened to the subject tissue structure, preferably in a pattern about the annulus of the translumenal access port, incremental pressure in the bladder or other mechanism may be utilized to uncouple the one or more closure clips from the balloon member, allowing them to assume an unloaded configuration preferably selected to cause tissue coaptation about the previous location of the translumenal access port to urge the port closed (160). With the port closed, the instruments may be withdrawn (162).

Referring back to FIG. 5C, an embodiment similar to that of FIG. 5B is depicted, with the exception that an elongate treatment probe (58), such as a bendable or steerable needle, comprising a series plurality (59) of distally-located treatment elements (akin to element 32) coupled to a helically shaped (48) treatment probe distal portion that is configured to be inserted and/or wrapped around a given tissue structure for discrete, controlled ablation of such tissue structure. The helical shape (48) is selected to minimize the risk of stenosis by longitudinally stretching out a circumferential lesion (i.e., a non-stretched purely circumferential lesion may have scar tissue expansion inward from directly opposing tissue structure portions, leaving it more vulnerable to stenosis by such scarring; the helical pitch shape 48 is configured to avoid this). An orthogonal view is depicted in FIG. 5D.

Referring to FIGS. 6A, 6B, and 8, a trans-ureteral renal nerve plexus denervation procedure is illustrated. As shown in FIG. 6A, a guide and sheath instrument assembly similar to that depicted in FIGS. 5A and 5B may be inserted through the urethra (52) and into the bladder (50) where it may be navigated to cannulate one of the ureters (8) and be directed toward the kidney (2), as shown in FIG. 6B. Referring to FIG. 6B, with the sheath instrument (22) desirably located and oriented relative to the renal artery (10) (confirmation of which may be assisted using ultrasound, fluoroscopy, and other imaging modalities), a transcutaneous access port may be created through an expanded balloon member (26) to provide an elongate guide instrument, such as a robotically steerable guide instrument (24) with relatively immediate retroperitoneal access to the outside of the renal artery, and therefore the renal plexus. Such access may be utilized to directly ablate and/or otherwise denervate selected portions of the renal plexus. A similar configuration may be utilized to conduct a trans-lumenal diagnostic and/or interventional procedure via various other anatomical situations. For example, in an embodiment similar to that described in reference to FIGS. 5A-5D and 6A-6B, an elongate steerable instrument configuration may be utilized to move through the lower gastrointestinal tract, up into the intestine, and be utilized to cross the intestine closely adjacent the renal plexus to conduct a similar denervation procedure from a different anatomic platform. One or more stents or stentlike members may be left behind to bolster or replace the closure provided by the clip-like elements (34), and such stent or stentlike member may be subsequently removed, as directed by the physician, in a manner similar to that conducted in certain conventional ureter wound closure scenarios.

Referring to FIG. 8, a process flow for such a procedure is illustrated. With a sheath instrument advanced across a urethra and into the bladder (60), steerability and navigation capabilities of the sheath instrument may be utilized to cannulate a ureter (potentially using an over-the-wire technique) (62). The distal portion of the sheath instrument may be advanced into an optimal position and orientation for accessing the retroperitoneal space adjacent the renal artery and renal plexus (64). A balloon member may be expanded into a guide instrument deployment configuration wherein ureter portions adjacent the balloon are slightly tensioned in an expansive manner from the balloon inflation; the kidneys may continue to drain using a lumen defined through at least a portion of the balloon and/or sheath member (68). A guide member may be advanced out of a side port formed in the balloon member to create a translumenal access port (in some embodiments utilizing over the wire or over the needle techniques) (70). With the translumenal access created, the guide instrument may be advanced toward the desired neuroanatomy (72) from the outside of the renal artery, and controlled denervation accomplished using radiofrequency energy emission or other denervation modalities, as described above (74). Subsequently, the instrumentation may be retracted, the access port closed (for example, as described above), the balloon deflated, and normal function returned without the endolumenal instrumentation in place (76).

Referring to FIG. 7, various aspects of the cardiovascular and neurological anatomy around the renal system are depicted to illustrate that there are several translumenal access opportunities to the retroperitoneal region of the renal plexus, including but not limited to the vena cava (6), the renal veins (12), the celiac trunk artery (54), and the superior mesentery artery (56). Referring to FIG. 9, a process for implementing a translumenal renal plexus denervation with a trans-celiac approach is illustrated. A sheath instrument is advanced up the aorta and into the celiac trunk artery (78). An over the wire process may be utilized to gain full access to the celiac trunk for the distal portion of the sheath instrument (80). The distal portion of the sheath may be adjusted in position and orientation to optimize a translumenal approach toward the renal plexus (82). A balloon member coupled to the distal portion of the sheath member may be expanded to slightly tension the celiac trunk portions adjacent the balloon member, and blood may continue to flow past the balloon member using a lumen formed through the balloon member (86). A guide instrument may be advanced out of a side port of the sheath instrument to create a transvascular access port (88). In one embodiment, a sharpened needle may be utilized for the initial advancement, followed by the guide instrument in an over the needle interfacing relationship. The distal portion of the guide instrument may be positioned adjacent the renal plexus (90), and one or more RF electrodes may be utilized to controllably denervate portions of the renal plexus (92). Subsequently the guide instrument may be retracted, the transvascular access port closed (for example, using one or more clip members as described above in reference to FIG. 5B), the sheath balloon member deflated, and the sheath instrument retracted to leave a complete closure (94).

Referring to FIG. 10, a process for implementing a translumenal renal plexus denervation with a trans-mesentary approach is illustrated. A sheath instrument is advanced up the aorta and into the superior mesentary artery (96). An over the wire process may be utilized to gain full access to the celiac trunk for the distal portion of the sheath instrument (98). The distal portion of the sheath may be adjusted in position and orientation to optimize a translumenal approach toward the renal plexus (100). A balloon member coupled to the distal portion of the sheath member may be expanded to slightly tension the superior mesentery artery portions adjacent the balloon member, and blood may continue to flow past the balloon member using a lumen formed through the balloon member (104). A guide instrument may be advanced out of a side port of the sheath instrument to create a transvascular access port (106). In one embodiment, a sharpened needle may be utilized for the initial advancement, followed by the guide instrument in an over the needle interfacing relationship. The distal portion of the guide instrument may be positioned adjacent the renal plexus (108), and one or more RF electrodes may be utilized to controllably denervate portions of the renal plexus (110). Subsequently the guide instrument may be retracted, the transvascular access port closed (for example, using one or more clip members as described above in reference to FIG. 5B), the sheath balloon member deflated, and the sheath instrument retracted to leave a complete closure (112).

Referring to FIG. 11, a process for implementing a translumenal renal plexus denervation with a trans-vena-cava approach is illustrated. A sheath instrument is advanced up into the vena cava from a femoral or other access point (114). The distal portion of the sheath may be adjusted in position and orientation to optimize balloon member positioning for a translumenal approach toward the renal plexus (116). A balloon member coupled to the distal portion of the sheath member may be expanded to slightly tension the celiac trunk portions adjacent the balloon member, and blood may continue to flow past the balloon member using a lumen formed through the balloon member (120). A guide instrument may be advanced out of a side port of the sheath instrument to create a transvascular access port (122). In one embodiment, a sharpened needle may be utilized for the initial advancement, followed by the guide instrument in an over the needle interfacing relationship. The distal portion of the guide instrument may be positioned adjacent the renal plexus (124), and one or more RF electrodes may be utilized to controllably denervate portions of the renal plexus (126). Subsequently the guide instrument may be retracted, the transvascular access port closed (for example, using one or more clip members as described above in reference to FIG. 5B), the sheath balloon member deflated, and the sheath instrument retracted to leave a complete closure (128).

Referring to FIG. 12, a process for implementing a translumenal renal plexus denervation with a renal vein approach is illustrated. A sheath instrument is advanced up the vena cava and into the renal vein (130). An over the wire process may be utilized to gain full access to the renal vein for the distal portion of the sheath instrument (132). The distal portion of the sheath may be adjusted in position and orientation to optimize a translumenal approach toward the renal plexus (134). A balloon member coupled to the distal portion of the sheath member may be expanded to slightly tension the celiac trunk portions adjacent the balloon member, and blood may continue to flow past the balloon member using a lumen formed through the balloon member (138). A guide instrument may be advanced out of a side port of the sheath instrument to create a transvascular access port (140). In one embodiment, a sharpened needle may be utilized for the initial advancement, followed by the guide instrument in an over the needle interfacing relationship. The distal portion of the guide instrument may be positioned adjacent the renal plexus (142), and one or more RF electrodes may be utilized to controllably denervate portions of the renal plexus (144). Subsequently the guide instrument may be retracted, the transvascular access port closed (for example, using one or more clip members as described above in reference to FIG. 5B), the sheath balloon member deflated, and the sheath instrument retracted to leave a complete closure (146).

Referring to FIGS. 14A-14G, various aspects of configurations selected to controllably denervate portions of a renal plexus or fibers thereof are illustrated. As shown in FIG. 14A, a robotic sheath instrument (22) and guide instrument (24) assembly is depicted being advanced up the aorta (4) and into the renal artery (10). The coaxial slidable coupling of the two robotic instruments is useful in the depicted embodiment for telescoping the smaller instrument relative to the larger, as depicted in FIGS. 14B and 14C, for example. In another embodiment, a single robotic guide type instrument may be utilized without the load-shielding and related fine-control benefits of having a “home base” sheath structure (22) positioned at the aorta (4) as shown, for example, in FIGS. 14B and 14C. In another embodiment, a non-robotic sheath may be utilized along with a robotic guide instrument (24). In yet another embodiment, two non-robotic instruments may be utilized, such as steerable catheters or sheaths that are responsive to non-electromechanical pullwire or pushwire loading for steerability.

Referring again to FIG. 14A, several nerve tissue strands (20) are depicted surrounding portions of the renal artery (10), as are groups of juxtaglomerular apparatus (or “JGA”) cells (198), which are known to be responsible, at least in part, for the production of renin in response to efferent neural signals through the fibers (20) of the renal plexus, and thereby correlated with increases in blood pressure. Also shown are several arterioles (196) where the renal artery (4) branches down to meet the kidney.

Referring to FIG. 14B, the larger sheath instrument (22) is positioned at the mouth of the renal artery (10) while the smaller guide instrument (24) preferably is electromechanically advanced, and navigated to avoid local tissue trauma. As described above in reference to FIGS. 5A-5D, the distal portion of the guide instrument (24) may be equipped with various sensors (i.e., such as ultrasound transducers, localization sensors, thermocouples, and/or radiation antennae such as microwave antennae for blackbody radiation sensing) and/or treatment elements (i.e., such as high intensity focused ultrasound transducers, RF electrodes, laser emission elements, fluid emission elements, and the like). Referring to FIG. 14C, further insertion of the guide instrument (24) into the renal artery is facilitated by the electromechanical control of a robotic catheter system, the navigation of which may be facilitated by imaging modalities such as transcutaneous ultrasound, transvascular ultrasound, intravascular ultrasound, fluoroscopy, and navigation within a registered three-dimensional virtual environment created using images from modalities such as computed tomography, 3-dimensional computed tomography, magnetic resonance, X-ray, fluoroscopy, and the like, as described, for example, in the aforementioned incorporated references. For example, in one embodiment, a “no touch” insertion may be accomplished utilizing the stability provided by the placement of the sheath instrument (22), along with the navigability of a registered and real-time (or near real-time) imaged robotically steerable guide instrument (24).

Referring to FIG. 14D, subsequent to cannulation of the renal artery (10) to a position approximately adjacent the renal arterioles (196), a brief mapping study or investigation may be executed. This mapping study may be preceded by preoperative or intraoperative imaging to determine at least some information regarding the positions, or likely positions, of aspects of the renal plexus. Referring again to FIG. 14D, in one embodiment, a flexible, expandable device (292), such as a controllably expandable balloon or stentlike structure, may be controllably deployed from the guide instrument (24) and expanded to provide a direct interface between the tissues of the subject lumen and circuit elements (294) of the expandable device (292), the circuit elements being configured to detect nearby electrical signals, and in one embodiment to be alternatively be utilized to treat the nearby tissues through the controllable flow of current therethrough. In one embodiment, a conformal electronics polymer material, such as that available under the tradename MC10® by MC10 Corporation of Cambridge, Mass., may be utilized to embed radiofrequency (“RF”) or other electrode circuitry within an inflatable or expandable substrate, as depicted in FIGS. 14D and 14E. Referring to the close up view of FIG. 14F, the circuit elements (294) may have sharpened probing portions (296) configured to protrude into nearby tissues, such as the walls of the renal artery (4), to gain closer proximity to signals passing through nearby neural structures, such as the depicted renal plexus fibers (20), and/or to gain closer proximity to structures to be denervated or altered in a treatment phase, such as by applying RF energy for selective denervation by heating. Full inflation or expansion of the associated expandable device (292) may be required to seat the probing portions (296) across portions of the nearby tissue structures, and the assembly of the expandable device (292), circuit elements (294), and probing portions (296) preferably is configured to be retractable back into the delivery instrument (24) without damage to nearby structures. In the embodiment depicted in FIGS. 14D-14F, deflation or controlled outer geometry shrinking of the expandable device (292), concomitant with incremental insertion of the guide instrument (24) and slight retraction of the expandable device (292), may be utilized to safely retract the expandable device after mapping and/or treatment.

Referring to FIG. 14G, in another embodiment, an individual probe member (298), such as an RF needle tip, may be utilized to selectively probe pertinent tissue structures for both mapping and treatment steps. Preferably the controller of the robotic catheter system is configured to not only controllably navigate the probe member (298) to locations of interest with a desirable insertion vector and insertion location, but also to store trajectory, path, location, and other information pertinent to each diagnostic and/or treatment step for constant monitoring of the procedure, and also ease of repeatability—or ease of avoiding repeatability (i.e., in scenarios wherein it is not desirable to conduct two RF heating bouts on the same tiny volume of tissue).

Referring to FIG. 14H, in one embodiment, a probe member (298) may be navigated directly to discrete JGA cells (198) or lesions of JGA cells to selectively destroy these directly. Any of the embodiments described herein may incorporate load sensing capabilities of the subject robotic catheter system, along with haptic input device features, to facilitate fine, atraumatic, predictable navigation of the diagnostic and/or treatment tools.

Referring to FIG. 15A, in another embodiment, an optical coherence tomography (or “OCT”) fiber (300) may be coupled between a distal lens (302) and a proximal emitter/interferometer (not shown; available from sources such as ThorLabs, Inc., of Newton, N.J.) to facilitate OCT tissue structure threshold sensing (i.e., the sensing and/or visualization of boundaries of nearby tissue structures, such as the renal artery (10) wall thresholds, nerve fiber 20 structure thresholds, and the like) with a virtual field of view (304) dependent upon the lens (302) and emissions parameters. Such OCT imaging analysis may be utilized not only to locate structures of interest, but also to treat such structures—with near-real-time analysis of not only the tissue structure thresholds, but also thresholds of other objects, such as RF electrode probe tips and the like. The embodiment of FIG. 15A features an OCT configuration wherein the lens (302) is located on a distal face of the guide instrument (24). Referring to FIG. 15B, an arcuate configuration of the OCT fiber (300) proximal to the side-oriented lens (302) and field of view (304) may be utilized for a side-capturing configuration. Referring to FIG. 15C, another side-capturing configuration is facilitated by a mirror or reflector (306) configured to reflect outgoing and incoming light signals as shown.

Referring to FIG. 15D, an embodiment is shown wherein a working volume (318) is evacuated of blood to facilitate greater flexibility with light-based imaging technologies, such as video and OCT. In other words, the embodiments of FIGS. 15A-15C showed the lens (302) purposefully in almost direct opposition to nearby tissue structures, to avoid scattering and other effects of red blood cells and other elements of flowing blood which may negatively impact such imaging. The embodiment of FIG. 15D addresses this concern by temporarily (i.e., for a short period of time, as dictated by the pathophysiology of the associated kidney and other tissue structures) evacuating the working volume (318) of blood. This is accomplished in the depicted embodiment by inflating two expandable occlusive elements (308, 310), such as balloons, and evacuating the captured blood using simple vacuum proximally through the sheath (22) and associated instruments. A larger delivery member (314) accommodates coupling of the guide instrument (24) and also the volume capture assembly, which comprises the two expandable occlusive elements (308, 310) and a coupling member (312). A guide instrument port (316) allows for slidable coupling of the proximal expandable occlusive element (310) and the guide instrument (24). With such a configuration, various imaging devices may be utilized to create images of nearby anatomy, such as ultrasound (in which case a transmissive medium, such as saline, may be pumped into the working volume for sound wave transmission enhancement and subsequently removed), CCD cameras, CMOS cameras, fiberscopes, and the like, in addition to the aforementioned imaging configurations such as OCT.

Referring to FIGS. 16-21, various process embodiments are illustrated wherein one or more minimally invasive instruments may be utilized in diagnostic and/or interventional medical procedures. Referring to FIG. 16, after a remotely steerable sheath catheter instrument is inserted into the aorta and navigated toward the renal artery (175), the renal artery may be cannulated, for example with a coaxially associated remotely steerable guide instrument that is movably coupled to the sheath instrument (174). An interactive imaging study, or steps thereof, may be conducted of the renal artery and associated neural anatomy using one or more minimally invasive imaging modalities, such as ultrasound, fluoroscopy, and/or OCT (176), as described above. The results of the imaging study may be utilized to create a mapping representation of the neural anatomy relative to the renal artery anatomy, for example, by stimulating one or more of the associated nerve fibers and observing resulting signal conduction (178). In other words, referring back to FIGS. 14E and 14F, in one embodiment, one or more of the proximal (i.e., closer to the aorta in the variation of FIG. 14E) circuit elements and/or associated probing portions (element 296 of FIG. 14F) may be used to stimulate or electrify adjacent nerve fiber (20) portions at such proximal position, and the conduction of such stimulation may be detected with each of the other circuit elements (294) to monitor or “map” the associated conduction pathways. The results of such mapping may be utilized in the selective denervation of portions of the renal plexus, for example, by transmitting current to heat and denervate such portions (180). The mapping configuration may then be utilized to confirm that the denervation was, indeed, successful, or to what extent, with further stimulation of the pertinent fibers and monitoring of the results. Further, renin levels, such as in the renal vein, may be monitored to determine a level of treatment success associated with the thermal denervation treatment. Similarly, alcohol and other fluids may be utilized and monitored for denervation. Ultimately, the pertinent instruments may be retracted and the vascular access closed (182).

Referring to FIG. 17, a process similar to that of FIG. 16 is depicted, with the exception that a venous route is utilized to conduct denervation near the renal artery. This is believed to be less clinically complicated in certain scenarios. The catheter instrumentation is inserted into the inferior vena cava and navigated toward the renal vein (184). The renal vein is cannulated with a guide instrument movably coupled to the sheath instrument (186). The imaging study is conducted not only on the neural anatomy, but also on the renal vein anatomy and renal artery anatomy to understand the relationships of these three and other nearby tissue structures (188). The results of the imaging study may be utilized as inputs in a mapping subprocess, wherein one or more nerve fibers may be stimulated and the resulting signal conduction observed (190). The neural anatomy map resulting from the mapping efforts may be utilized for selective denervation treatment of the renal plexus (192), as well as in generating feedback to an operator regarding the effectiveness of various denervation attempts (as described above, renin levels also may be monitored). Subsequently the instruments may be retracted and the vascular access closed (194).

The embodiment of FIG. 18 illustrates that process configurations such as those described above in reference to FIGS. 16 and 17 may be broadly applied to many tissue structures that define one or more lumens through which the pertinent instrumentation may be advanced and utilized. Referring to FIG. 18, a catheter instrument may be inserted into the tissue structure defining a lumen believed to be associated with targeted neural tissue (252). The lumen may be cannulated with the catheter instrument (254). An interactive imaging study may be conducted to create an image-based anatomic mapping representation of the neural anatomy and other pertinent tissue structures (256), and an expandable device such as that described in reference to FIGS. 14E and 14F may be utilized to observe signal conduction (258) and create an electrical mapping which may be utilized to monitor the effectiveness of the treatment steps (260). Subsequently the instrumentation may be removed and access to the pertinent lumens and/or tissue structures discontinued (262).

FIG. 19 illustrates aspects of an embodiment wherein a robotically-steerable catheter instrument specifically is utilized (as described above, the aforementioned catheter instruments may or may not be remotely electromechanically navigable). With the robotic catheter instrumentation inserted into the pertinent lumen, such as an aorta in this example (264), precision navigation and control features of the robotic instrument may be utilized during the insertional navigation (266), anatomic imaging may be conducted (268), electrical mapping may be conducted (270), and selective denervation may be conducted (272), followed by removal of the pertinent instrumentation and closure of the vascular access (274).

FIG. 21 illustrates a related embodiment with the additional step depicted (290) of observing feedback indicators, such as renin levels in blood exiting the renal vein and/or neural conduction paradigms with the mapping configuration, as confirming techniques for monitoring and/or adjusting treatment in a closed loop type of configuration.

Referring to FIG. 20, a robotic catheter system such as that described and incorporated above may be utilized to operate an off-the-shelf treatment head such those available on instruments from the Ardian division of Medtronic Corporation, to improve the navigability of such treatment head, and combine the treatment capabilities of such treatment head with additional diagnostic and treatment capabilities, such those described herein. As shown in FIG. 20, after a renal plexus denervation treatment head has been coupled to a distal portion of a robotic catheter instrument (276), the instrument may be inserted into an aorta or other lumen and navigated toward the renal artery or other targeted tissue structure (278). In the depicted renal intervention embodiment, the renal artery may be cannulated using the navigation control of the robotic instrumentation (280), after which an anatomic imaging study may be conducted (282), an electrical mapping study conducted (284), selective denervation attempted with feedback from the mapping configuration (286), and subsequent removal of the instruments and closure of the access (288).

Referring to FIG. 22, in another embodiment, a configuration similar to that depicted in FIG. 14G is depicted, and in the embodiment of FIG. 14G, is being operated to create a pattern of treatments (200) that is substantially elliptical, and that is configured to reduce the chances of post-intervention stenosis or other complications, due to the fact that the treatment contacts forming the pattern are spread over a larger length, longitudinally, of the targeted tissue structure (here a renal artery 10). Other patterns may be created within the defined lumen space, such as sets of curves, portions of circumferential lines, and the like.

Referring to FIGS. 23A-23C, a configuration is illustrated wherein a substantially helical treatment element (320) configured to conform to the targeted lumen (here a renal artery 10 lumen) may be pushed out the distal end of the delivery system (here a robotic sheath instrument 24), and then pulled back (322) proximally as the instrument (24) is withdrawn proximally, creating an opportunity to cause RF electrodes or other treatment elements coupled to the helical member (320) to create a longitudinal lesion configured to denervate targeted nerve fibers (20) which may be disposed about the targeted lumen. The treatment elements coupled to the helical member (320) may be configured or operated to remain in an “on” mode (i.e., treatment inducing; such as current flow mode with RF electrode treatment elements) during pullback (322), or may be configured to switch on and off intermittently with various patterns over time, such patterns being pre-programmable. FIGS. 23B and 23C illustrate further pullback (322) of the treatment assembly (24, 320), which may be automated using an “autoretract” functionality of the robotic guide/sheath catheter systems, descriptions of which are incorporated by reference herein.

Referring to FIG. 24, a set of expandable members (308, 310, such as a set of two balloons) may be used to isolate the nearby treatment environment for a diagnostic/treatment configuration (292, 294) such as that depicted in FIGS. 14D-14F. As shown in FIG. 24, a distal expandable balloon member (308), coupled to a proximal expandable balloon member (310) by a coupling member (312) that preferably defines an inflation lumen for the distal expandable balloon member (310), may be inserted in a collapsed form (not shown) through a lumen defined through the guide instrument (24), expanded (as illustrated), and utilized to vacuum away blood captured in the capture volume (318) for diagnostic and/or treatment steps. With the capture volume isolated, carbon dioxide or other bioinert gases, or saline, may be infused through an infusion lumen fluidly coupled to the capture volume (318) through one or more of the elongate proximal instruments (24, 22, 312) to facilitate diagnostic and/or treatment steps, such as improved tissue apposition, improved electrical conduction, and/or improved imaging and/or visualization, such as direct visualization using an associated fiber imaging bundle or imaging chip configured to have a field of view within or adjacent to the capture volume, or an ultrasound or OCT imaging configuration as described above.

Referring to FIGS. 25A and 25B, in another embodiment, two or more elongate steerable instruments (24, 25) may be utilized simultaneously from the same sheath instrument (23) configured to host and stabilize both guide instruments (24, 25) and advance a plurality of diagnostic and/or interventional probe members (298, 299). Such a sheath/guide configuration is described in the aforementioned incorporated by reference disclosures, and may be utilized herein to expedite and improve upon diagnostic and treatment steps as described above. For example, such a configuration may be utilized to create diametrically opposed lesions, to facilitate faster pattern creation, as described in reference to FIG. 22, and to assist with load-counterload relationships in delicate tissue intervention. FIG. 25B illustrates an embodiment emphasizing that the sheath instrument (23, or 24 in other depictions herein) may be advanced distally into the renal artery or other subject tissue structure lumen, to provide easy access for one or more guide instruments (24, 25) to the arterioles (196) or other distal structures, which may be advantageous for direct diagnostics and intervention pertinent to the JGA cells, for example.

In another embodiment, a stent or stentlike member configured to elute one or more drugs or compounds configured to denervate the nearby targeted neural plexus tissue may be deployed into a structure of interest, such as a renal artery or renal vein, to accomplish such denervation over a designated period of time, after which the stent or stentlike member may be removed, resorbed, or left in place as a substantially bioinert prosthesis.

Referring to FIGS. 26A-26C, another embodiment is illustrated wherein a steerable sheath (22) and guide instrument (24) assembly may be utilized to provide direct access for a pre-shaped or pre-bent interventional instrument, such as a pre-bent J-curve instrument (352) featuring a bent electrode portion (354) configured to create a lesion in the same shape when current is flowed through the electrode portion (354) and into nearby tissue structures, such as the interior of the renal artery (10), as shown, or portions of the renal vein, nearby renal nerve strands (20), JGA cells (198), and the like. In one embodiment, in a manner similar to that described above in reference to FIGS. 23A-23C, wherein a pre-bent spiral or helical instrument (320) is pulled back through the associated vessel, the arcuate or curved interventional instrument of FIGS. 26A-26C may also be controllably pulled back to create an elongate lesion to disrupt the pre-existing electrical communication pathways of the nearby neural plexus tissue. FIGS. 26B and 26C show additional levels of progression of pullback (350). In another embodiment, the instrument (352) may be controllably rotated during pullback, or during a portion of pullback, to establish a predetermined pattern of contact between the electrode portion (354) and the surrounding tissue structures (10, 20, 198, 196). During pullback, current may be either continuously flowed through the electrode portion (354), in which case a “long linear lesion” may be produced in a solid (i.e., noninterrupted) linear, curvy, or other pattern, or the current may be discontinuously flowed through the electrode portion (354), creating a “long linear lesion” may be produced in a discontinuous (i.e., interrupted) linear, curvy, or other pattern.

Referring to FIGS. 27A-27C, further details regarding aspects of a helical or spiral type pre-bent or pre-formed instrument treatment element (320) may be formed and configured to behave are illustrated. Referring to FIG. 27A, a series of spiral windings (360) created on a mandrel (358) may be utilized to form a helical or spiral pre-bent or pre-formed shape into a wire (356). Heat treatment may be utilized to maintain this form for the wire (356) after removal of the mandrel, as shown in FIG. 27B, wherein the spiral wire (356) is shown coupled to a piece of metal hypotube (364) via a metallic crimpling coupler (362), which provides the wire (356) with a proximal handle or deliver member for operative manipulation. Referring to FIG. 27C, depending upon what materials are utilized for the wire (356), it may be placed in a restraining tube or lumen (366) that radially constrains the outer diameter of the spiral—an in such radially-collapsed configuration, the instrument may be configured to still retain the generally spiral or helical configuration until it is released from such constraint, after which it may be configured to return to the radially expanded configuration, as in FIG. 27B.

Referring to FIG. 28A, in one embodiment, a J-curve type arcuate instrument (352) may be formed by taking a J-curve-shaped insulated guidewire, such as those available from Terumo Corporation, and removing a portion of the polymeric outer insulation, for example, with a knife or other sharp instrument, to leave behind an exposed metallic core portion which may be utilized as a conductive electrode portion (370), and distal (372) and proximal (368) portions which remain insulated and generally nonconductive relative to the conductive electrode portion (370). A farther out perspective view is shown in FIG. 28B.

Referring to FIGS. 29-34, various process embodiments are illustrated wherein one or more minimally invasive instruments may be utilized in diagnostic and/or interventional medical procedures utilizing pre-shaped instruments as described above. Referring to FIG. 16, after a remotely steerable sheath catheter instrument is inserted into the aorta and navigated toward the renal artery (175), the renal artery may be cannulated, for example with a coaxially associated remotely steerable guide instrument that is movably coupled to the sheath instrument (174). An interactive imaging study, or steps thereof, may be conducted of the renal artery and associated neural anatomy using one or more minimally invasive imaging modalities, such as ultrasound, fluoroscopy, and/or OCT (176), as described above. The results of the imaging study may be utilized to create a mapping representation of the neural anatomy relative to the renal artery anatomy, for example, by stimulating one or more of the associated nerve fibers and observing resulting signal conduction (178). In other words, referring back to FIGS. 14E and 14F, in one embodiment, one or more of the proximal (i.e., closer to the aorta in the variation of FIG. 14E) circuit elements and/or associated probing portions (element 296 of FIG. 14F) may be used to stimulate or electrify adjacent nerve fiber (20) portions at such proximal position, and the conduction of such stimulation may be detected with each of the other circuit elements (294) to monitor or “map” the associated conduction pathways. The results of such mapping may be utilized in the selective denervation of portions of the renal plexus using a pre-shaped instrument such as a J-curved or spiral shaped instrument, for example, by transmitting current to heat and denervate such portions (324). The mapping configuration may then be utilized to confirm that the denervation was, indeed, successful, or to what extent, with further stimulation of the pertinent fibers and monitoring of the results. Further, renin levels, such as in the renal vein, may be monitored to determine a level of treatment success associated with the thermal denervation treatment. Similarly, alcohol and other fluids may be utilized and monitored for denervation. Ultimately, the pertinent instruments may be retracted and the vascular access closed (326).

Referring to FIG. 30, a process similar to that of FIG. 29 is depicted, with the exception that a venous route is utilized to conduct denervation near the renal artery. This is believed to be less clinically complicated in certain scenarios. The catheter instrumentation is inserted into the inferior vena cava and navigated toward the renal vein (184). The renal vein is cannulated with a guide instrument movably coupled to the sheath instrument (186). The imaging study is conducted not only on the neural anatomy, but also on the renal vein anatomy and renal artery anatomy to understand the relationships of these three and other nearby tissue structures (188). The results of the imaging study may be utilized as inputs in a mapping subprocess, wherein one or more nerve fibers may be stimulated and the resulting signal conduction observed (190). The neural anatomy map resulting from the mapping efforts may be utilized for selective denervation treatment of the renal plexus using a pre-shaped instrument, such as a j-shaped or spiral-shaped guidewire containing one or more electrodes (328), as well as in generating feedback to an operator regarding the effectiveness of various denervation attempts (as described above, renin levels also may be monitored). Subsequently the instruments may be retracted and the vascular access closed (330).

The embodiment of FIG. 31 illustrates that process configurations such as those described above in reference to FIGS. 29 and 30 may be broadly applied to many tissue structures that define one or more lumens through which the pertinent instrumentation may be advanced and utilized. Referring to FIG. 31, a catheter instrument may be inserted into the tissue structure defining a lumen believed to be associated with targeted neural tissue (252). The lumen may be cannulated with the catheter instrument (254). An interactive imaging study may be conducted to create an image-based anatomic mapping representation of the neural anatomy and other pertinent tissue structures (256), and an expandable device such as that described in reference to FIGS. 14E and 14F may be utilized to observe signal conduction (258) and create an electrical mapping which may be utilized to monitor the effectiveness of the treatment steps with the pre-shaped instrumentation (332). Subsequently the instrumentation may be removed and access to the pertinent lumens and/or tissue structures discontinued (334).

FIG. 32 illustrates aspects of an embodiment wherein a robotically-steerable catheter instrument specifically is utilized (as described above, the aforementioned catheter instruments may or may not be remotely electromechanically navigable). With the robotic catheter instrumentation inserted into the pertinent lumen, such as an aorta in this example (264), precision navigation and control features of the robotic instrument may be utilized during the insertional navigation (266), anatomic imaging may be conducted (268), electrical mapping may be conducted (270), and selective denervation may be conducted using pre-shaped instruments (336), followed by removal of the pertinent instrumentation and closure of the vascular access (338). FIG. 34 illustrates a related embodiment with the additional step depicted (346) of observing feedback indicators, such as renin levels in blood exiting the renal vein and/or neural conduction paradigms with the mapping configuration, as confirming techniques for monitoring and/or adjusting treatment in a closed loop type of configuration. Steps 344 and 348 of the embodiment of FIG. 34 are similar to steps 336 and 338 of the embodiment of FIG. 32.

Referring to FIG. 33, a robotic catheter system such as that described and incorporated above may be utilized to operate an off-the-shelf treatment head such as those available on instruments from the Ardian division of Medtronic Corporation, to improve the navigability of such treatment head, and combine the treatment capabilities of such treatment head with additional diagnostic and treatment capabilities, such those described herein. As shown in FIG. 20, after a renal plexus denervation treatment head has been coupled to a distal portion of a robotic catheter instrument (276), the instrument may be inserted into an aorta or other lumen and navigated toward the renal artery or other targeted tissue structure (278). In the depicted renal intervention embodiment, the renal artery may be cannulated using the navigation control of the robotic instrumentation (280), after which an anatomic imaging study may be conducted (282), an electrical mapping study conducted (284), selective denervation attempted with feedback from the pre-shaped instrument mapping configuration (340), and subsequent removal of the instruments and closure of the access (342).

Any of the aforementioned deployed structures may comprise resorbable materials in addition to the aforementioned nonresorbable materials—to facilitate combinations and permutations which may be completely resorbed, leaving behind a biologically healed access wound.

Further, any of the aforementioned configurations may be applied to other tissue structure configurations involving natural lumens to be navigated, and nearby neural or other tissue structures to be targeted. For example, the techniques and configurations herein may be applied to other aspects of the cardiovascular and renal/urinary systems, as well as other anatomic subsystems including but not limited to the respiratory, upper gastric, and lower gastric subsystems.

Various exemplary embodiments of the invention are described herein. Reference is made to these examples in a non-limiting sense. They are provided to illustrate more broadly applicable aspects of the invention. Various changes may be made to the invention described and equivalents may be substituted without departing from the true spirit and scope of the invention. In addition, many modifications may be made to adapt a particular situation, material, composition of matter, process, process act(s) or step(s) to the objective(s), spirit or scope of the present invention. Further, as will be appreciated by those with skill in the art that each of the individual variations described and illustrated herein has discrete components and features which may be readily separated from or combined with the features of any of the other several embodiments without departing from the scope or spirit of the present inventions. All such modifications are intended to be within the scope of claims associated with this disclosure.

Any of the devices described for carrying out the subject interventions may be provided in packaged combination for use in executing such interventions. These supply “kits” further may include instructions for use and be packaged in sterile trays or containers as commonly employed for such purposes.

The invention includes methods that may be performed using the subject devices. The methods may comprise the act of providing such a suitable device. Such provision may be performed by the end user. In other words, the “providing” act merely requires the end user obtain, access, approach, position, set-up, activate, power-up or otherwise act to provide the requisite device in the subject method. Methods recited herein may be carried out in any order of the recited events which is logically possible, as well as in the recited order of events.

Exemplary aspects of the invention, together with details regarding material selection and manufacture have been set forth above. As for other details of the present invention, these may be appreciated in connection with the above-referenced patents and publications as well as generally known or appreciated by those with skill in the art. For example, one with skill in the art will appreciate that one or more lubricious coatings (e.g., hydrophilic polymers such as polyvinylpyrrolidone-based compositions, fluoropolymers such as tetrafluoroethylene, hydrophilic gel or silicones) may be used in connection with various portions of the devices, such as relatively large interfacial surfaces of movably coupled parts, if desired, for example, to facilitate low friction manipulation or advancement of such objects relative to other portions of the instrumentation or nearby tissue structures. The same may hold true with respect to method-based aspects of the invention in terms of additional acts as commonly or logically employed.

In addition, though the invention has been described in reference to several examples optionally incorporating various features, the invention is not to be limited to that which is described or indicated as contemplated with respect to each variation of the invention. Various changes may be made to the invention described and equivalents (whether recited herein or not included for the sake of some brevity) may be substituted without departing from the true spirit and scope of the invention. In addition, where a range of values is provided, it is understood that every intervening value, between the upper and lower limit of that range and any other stated or intervening value in that stated range, is encompassed within the invention.

Also, it is contemplated that any optional feature of the inventive variations described may be set forth and claimed independently, or in combination with any one or more of the features described herein. Reference to a singular item, includes the possibility that there are plural of the same items present. More specifically, as used herein and in claims associated hereto, the singular forms “a,” “an,” “said,” and “the” include plural referents unless the specifically stated otherwise. In other words, use of the articles allow for “at least one” of the subject item in the description above as well as claims associated with this disclosure. It is further noted that such claims may be drafted to exclude any optional element. As such, this statement is intended to serve as antecedent basis for use of such exclusive terminology as “solely,” “only” and the like in connection with the recitation of claim elements, or use of a “negative” limitation.

Without the use of such exclusive terminology, the term “comprising” in claims associated with this disclosure shall allow for the inclusion of any additional element—irrespective of whether a given number of elements are enumerated in such claims, or the addition of a feature could be regarded as transforming the nature of an element set forth in such claims. Except as specifically defined herein, all technical and scientific terms used herein are to be given as broad a commonly understood meaning as possible while maintaining claim validity.

The breadth of the present invention is not to be limited to the examples provided and/or the subject specification, but rather only by the scope of claim language associated with this disclosure. 

1. A robotic instrument system, comprising: a. a controller configured to control actuation of at least one servo motor; and b. an elongate instrument configured to move in response to actuation of the at least one servo motor; wherein the controller controls positioning of the instrument based at least in part upon an electroanatomic model of the neural plexus adjacent the renal artery.
 2. The system of claim 1, further comprising a master input device operatively coupled between the remotely-steerable elongate deployment member and the controller, the master input device configured to receive commands from an operator and produce control signals to be used by the controller to operate the elongate instrument.
 3. The system of claim 1, wherein the elongate instrument is an electromechanically steerable catheter.
 4. The system of claim 1, further comprising a robotic instrument driver operatively coupled between the elongate instrument and the controller, the robotic instrument driver being configured to move one or more control elements of the elongate instrument in response to signals transmitted from the controller to cause navigation movement of the elongate instrument.
 5. The system of claim 1, wherein the elongate instrument is coupled to a treatment element configured to be at least partially pierced into nearby tissue structures.
 6. The system of claim 1, further comprising one or more localization sensors coupled to a distal portion of the elongate instrument and configured to facilitate computation of a location of said distal portion relative to a coordinate system, wherein the localization sensor comprises an element selected from the group consisting of: an ultrasound transducer, an electromagnetic flux sensor, a fiber Bragg local deflection sensor, a resistive strain gauge, a potential difference sensor, and a current sensor.
 7. The system of claim 1, further comprising one or more imaging elements coupled to the elongate instrument selected from the group consisting of: an ultrasound transducer, an optical fiber, and an imaging chip.
 8. The system of claim 7, wherein one imaging element is an optical fiber, and wherein the system further comprises an interferometry system configured to analyze transmitted and reflected light signals.
 9. The system of claim 8, wherein the interferometry system is configured to create an OCT image of a portion of a targeted tissue structure.
 10. The system of claim 1, wherein the electroanatomic model comprises one or more spatial points of presence of neural fibers comprising the neural plexus relative to other nearby anatomy.
 11. The system of claim 1, wherein the controller is configured to advance the treatment element across at least one tissue wall toward the neural plexus.
 12. The system of claim 1, wherein the controller is configured to automatically move the elongate instrument based at least in part upon the electroanatomical model.
 13. The system of claim 1, wherein the controller is further configured to control positioning of the instrument based at least in part upon a renin level detected in the blood.
 14. The system of claim 1, wherein the controller is further configured to control a level of current flow to an ablation electrode operatively coupled to the instrument based at least in part upon a renin level detected in the blood.
 15. The system of claim 1, wherein the controller is configured to superimpose an anatomic map upon an electrical mapping to assist in the identification of electrical foci within the neural plexus adjacent the renal artery.
 16. A method for conducting a denervation process upon the neural plexus adjacent the renal artery, comprising: a. navigating a steerable catheter into the renal vein; b. imaging targeted portions of the neural plexus from inside of the renal vein to create an anatomic map of the targeted portions; c. creating an electrical mapping of one or more neural strands comprising the targeted portions; and d. denervating the targeted portions utilizing a treatment element coupled to the steerable catheter, based at least in part upon the anatomic map and electrical mapping.
 17. The method of claim 16, wherein the steerable catheter is a robotic catheter operatively coupled to the control computing device and configured to move in response to control signals from a master input device configured to manually operated by an operator.
 18. The method of claim 16, wherein creating an electrical mapping comprises stimulating a first portion of a nerve strand and detecting conduction of the stimulation at a second portion of the nerve strand longitudinally displaced from the first portion.
 19. The method of claim 18, further comprising associating a nerve anatomical location with each of the first and second portions of the nerve strand.
 20. The method of claim 19, further comprising associating a renal vein anatomical location from the anatomic map with each of the nerve anatomical locations to form an electroanatomical map.
 21. The method of claim 16, wherein the treatment element comprises an electrode and denervating comprises passing current through the electrode.
 22. The method of claim 21, wherein denervating further comprises placing the electrode at an endolumenal location adjacent a targeted portion of the neural plexus.
 23. The method of claim 21, wherein denervating further comprises placing the electrode at a translumenal location adjacent a targeted portion of the neural plexus.
 24. The method of claim 23, further comprising advancing the treatment element relative to a distal portion of the steerable catheter.
 25. The method of claim 16, further comprising superimposing the anatomic map upon the electrical mapping to assist in the identification of electrical foci within the neural plexus adjacent the renal artery.
 26. The method of claim 16, wherein creating an electrical mapping comprises stimulating a first portion of a nerve strand and detecting conduction of the stimulation in any other portion of the associated neural plexus.
 27. A system for conducting a denervation of the neural plexus adjacent the renal artery, comprising: a. a remotely-steerable elongate deployment member configured to be navigated into the renal artery; b. an expandable intravascular treatment member coupled to a portion of the elongate deployment member, the expandable member comprising one or more circuit elements operatively coupled to one or more tissue probing tips, such that upon expansion of the expandable member from a collapsed state to an expandable state, the probing tips protrude substantially perpendicularly from an outer surface of the expandable member and into one or more walls of the renal artery; and c. an energy source operatively coupled to the circuit elements and probing tips, the energy source configured to cause current to flow from the probing tips and cause localized heating sufficient to denervate nearby neural tissue.
 28. The system of claim 27, wherein the remotely-steerable elongate deployment member is electromechanically actuated.
 29. The system of claim 27, further comprising one or more localization sensors coupled to a distal portion of the remotely-steerable elongate deployment member and configured to facilitate computation of a location of said distal portion relative to a coordinate system, wherein the localization sensor comprises an element selected from the group consisting of: an ultrasound transducer, an electromagnetic flux sensor, a fiber Bragg local deflection sensor, a resistive strain gauge, a potential difference sensor, and a current sensor.
 30. The system of claim 27, further comprising one or more imaging elements coupled to the remotely-steerable elongate deployment member selected from the group consisting of: an ultrasound transducer, an optical fiber, and an imaging chip.
 31. The system of claim 30, wherein one imaging element is an optical fiber, and wherein the system further comprises an interferometry system configured to analyze transmitted and reflected light signals.
 32. The system of claim 31, wherein the interferometry system is configured to create an OCT image of a portion of a targeted tissue structure.
 33. The system of claim 31, further comprising a lens optically coupled to the optical fiber.
 34. The system of claim 33, wherein the lens and optical fiber define a field of view that is oriented along a longitudinal axis of the elongate deployment member.
 35. The system of claim 33, wherein the lens and optical fiber define a field of view that is oriented substantially perpendicular to a longitudinal axis of the elongate deployment member.
 36. The system of claim 27, wherein the expandable intravascular treatment member comprises a stent.
 37. A method of closing a translumenal access port defined through a side of a lumen, comprising: a. applying a circumferential clip from the inside of the lumen to effect a temporary closure, the clip being urged into a closed position by an inflatable actuating member local to the clip and controlled remotely by an operator; and b. deploying a stent over the closed position of the clip.
 38. The method of claim 37, further comprising imaging tissue structures adjacent the translumenal access port from inside of the lumen.
 39. The method of claim 38, wherein imaging comprises activating one or more ultrasound transducers.
 40. The method of claim 37, wherein the circumferential clip comprises a shape selected to circumferentially surround the translumenal access port.
 41. The method of claim 37, wherein applying the clip comprises urging one or more barb members of the clip into tissue surrounding the translumenal access port.
 42. The method of claim 37, wherein the inflatable actuating member comprises an inflatable bladder and wherein applying the clip comprises causing the bladder to inflate. 